I look at this from a historical position as it has been outplayed from the beginning as to the understanding that gravity in the universe can have it's counterpart revealed the action of a phenomenology search for the dark matter constituents while describing the state of the uinverse.

The type of detective work described by Sherlock Holmes has been used by astronomers for a long time to deepen our understanding of the universe. Ever since the phenomenal success of Isaac Newton in explaining the motion of the planets with his theory of gravity and laws of motion in 1687, unseen matter has been invoked to explain puzzling observations of cosmic bodies.

For example, the anomalous motion of Uranus led astronomers to suggest that an unseen planet existed, and a few years later, in 1846, Neptune was discovered. This procedure is still the primary method used to discover planets orbiting stars. A similar line of reasoning led to the detection in 1862, of the faint white dwarf Sirius B in orbit around the bright star Sirius.

In contrast, the attempt to explain the anomalies in the motion of Mercury as due to the existence of a new planet, called Vulcan, did not succeed. The solution turned out to be Einstein's theory of general of relativity, which modified Newton's theory.

Today, astronomers are faced with a similar, though much more severe, problem. Unlike the case of Uranus, where the gravity of Neptune adds a fraction of a percent to the gravitational force acting of Uranus, the extra force needed in the cases described below is several hundred percent! It is no exaggeration to say that solving the dark matter problem will require a profound change in our understanding of the universe. See:Field Guide to Dark Matter

So given the outlay of experiential work to the subject there would be those that counter the proposal to support such research because they believe that such an exercise if fruitless to solving the nature of the cosmos and the way the universe could be expanding according to some speeding up of a gravitational consideration ?

Tuesday, May 25, 2010

Conclusion:The state of mind of the observer plays a crucial role in the perception of time.Einstein

SPOILER ALERT:

To make a very, very long story short we discovered via Christian Shephard aka Jack’s dead father that all of the people on Oceanic 815 including Desmond, Daniel, Charlotte, Kate, Sawyer, Miles, Lapidus, Claire, Sayid, Sun, Jin, Richard, Michael, Walt, Miles, Ana Lucia, Locke, Hurley and Benjamin did really live on the island but when they died they moved on to L.A for their afterlife where they had the life that they always dreamed off. In The End we learned that those who did eventually find a way to forgive the people who hurt them , and forgave themselves were reunited with the people who meant something to them an went to heaven.See:Lost Finale Explanation:Lost Purgatory Ending Theories

Lost as in the emotive experience, as the "physiological and mental connection of being" winds down.

I thought what was very special was the recognition of all the memories traveling one path, all the fabrications of six years of Lost, to realize that they all could had been traveling in the after death consciousness. I mean, the fabrications of the island was a mass illusion, to support experience, while all the emotions are played out with each of the persons involved "until they finally recognized each other enough" to gather one more time in the church.

What was special is that as each person is awakened to the reality of where they are, by thefinal touch of love that connects the souls to that deeper level of recognition, while the memories of all that the had gone before was moved through flashes of realization that brought the experience together, culminating in the chance to go through the final gate to the light.

The island was hell. To burn out the light was to extinguish any hope of the light to support the illusions of the island and of the life of those in the after death consciousness.

I mean there are a lot of discrepancies once you realize that not all the people are there. A plane did escape, yet, there is no record of those people, while the focus was on a core group. The main actors I guess.

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I think the journey to understanding the whole thing is to understand the "heaviness that supports the contention as gravity" is to evolve through the scientific understanding, as the ancients did, looking toward cosmology.

That the continued evolution toward GR, is to solidify our understanding of the inverse square law of our positions in context of the life experience? Not just of the planets and galaxies held to the fabric of spacetime in the universe?

The general theory of relativity is as yet incomplete insofar as it has been able to apply the general principle of relativity satisfactorily only to gravitational fields, but not to the total field. We do not yet know with certainty by what mathematical mechanism the total field in space is to be described and what the general invariant laws are to which this total field is subject. One thing, however, seems certain: namely, that the general principal of relativity will prove a necessary and effective tool for the solution of the problem for the total field.Out of My Later Years, Pg 48, Albert Einstein

If you were to believe that the "books of the dead" Tibetan or Egyptian were really about books of life, then in the case of the Tibetan, the "clear light" was preceded "by the lost in reliving experiences, as in the fog of not understanding, or smoke, as in the show Lost. It is about moving toward that Clear light. That we could be lost for a time, and why, beside the death beds practitioners would help the soul travel through the ether of being of the experienced that they gained in life.

If the heart was free from the impurities of sin, and therefore lighter than the feather, then the dead person could enter the eternal afterlife.

If you take this last ancient plate and the wording below as to the experience one can have, it does not seem to unlikely that our way in the after death world can be constructed according too, the heaviness with which we can experience life emotively. If you understanding Einstein's conclusion, as to the pretty girl and the hot stove, then you understand that experience can have it's durations too.

Thursday, May 13, 2010

Just weeks after NASA astronauts repaired the Hubble Space Telescope in December 1999, the Hubble Heritage Project snapped this picture of NGC 1999, a nebula in the constellation Orion. The Heritage astronomers, in collaboration with scientists in Texas and Ireland, used Hubble's Wide Field Planetary Camera 2 (WFPC2) to obtain the color image.

NGC 1999 is an example of a reflection nebula. Like fog around a street lamp, a reflection nebula shines only because the light from an embedded source illuminates its dust; the nebula does not emit any visible light of its own. NGC 1999 lies close to the famous Orion Nebula, about 1,500 light-years from Earth, in a region of our Milky Way galaxy where new stars are being formed actively. The nebula is famous in astronomical history because the first Herbig-Haro object was discovered immediately adjacent to it (it lies just outside the new Hubble image). Herbig-Haro objects are now known to be jets of gas ejected from very young stars.

The NGC 1999 nebula is illuminated by a bright, recently formed star, visible in the Hubble photo just to the left of center. This star is cataloged as V380 Orionis, and its white color is due to its high surface temperature of about 10,000 degrees Celsius (nearly twice that of our own Sun). Its mass is estimated to be 3.5 times that of the Sun. The star is so young that it is still surrounded by a cloud of material left over from its formation, here seen as the NGC 1999 reflection nebula.

Friday, May 07, 2010

No matter what you call it, though, that substance and others similar to it could be the most-perfect fluids in existence because they have ultra-low viscosity, or resistance to flow, said Dam Thanh Son, an associate physics professor in the Institute for Nuclear Theory at the University of Washington.

Son and two colleagues used a string theory method called the gauge/gravity duality to determine that a black hole in 10 dimensions - or the holographic image of a black hole, a quark-gluon plasma, in three spatial dimensions - behaves as if it has a viscosity near zero, the lowest yet measured.

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2. A quark-gluon plasma, with the same quarks, but with "bags" disappeared and gluons flying around in their place. See: Just in case anyone forgot...

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One of the things I worked a lot on in earlier months this year (and late ones of last year) was the lead article in a cluster of articles that has appeared in the last few days in May’s special edition of Physics Today. They are sort of departmental-colloquium-level articles, so for a general physics audience, more or less. It’s about some of the things I’ve told you about here in the past (see e.g. here and here), concerning exciting and interesting applications of string theory to various experiments in nuclear physics, as well as atomic and condensed matter physics (although we do not have an article on the latter in this cluster). I had a fun time working with Peter Steinberg on the article and remain grateful to him for getting us all together in the first place to talk about this topic way back in that AAAS symposium of 2009. It was there that Steven Blau of Physics Today got the excellent idea to approach us all to do an article, which resulted in this special issue....See: The Search For Perfection…

Cover: In contrast with everyday liquids such as the oil and water shown on the cover, a so-called perfect fluid has exceedingly low shear viscosity. But unlike a superfluid, the perfect fluid is not in a single quantum state. Three articles in this issue explore the connection to string theory (beginning on page 29) and the possible existence of perfect fluids in two very different regimes: ultracold fermionic atoms (page 34) and ultrahot nuclear matter (page 39). (Photo by Stefan Kaben.)

Sunday, May 02, 2010

Physicists theorize that the omnipresent Higgs field slows some particles to below light speed, and thus imbues them with mass. Are we there yet?

How many of you with children have not heard our own children speak with impatience of wanting to be "there" and having to sit a long time before this is even possible?

Well, can you imagine the patience it took to materialize the experiments at Cern, in asking fundamental question about nature? It took a lot of patience and careful planning. There is no doubt about this.

I would also ask that those that visit this blog examine the picture below, as to the nature of "First Principle," in terms of computerized data, so that you understand this in context of an algorithm written, it is but the very essence of how something could have arisen in nature, had to be written into the "data accumulation" in order for us to recognize what is at the frontier of this experiment/knowledge in question.

The question of symmetry placed in this idea of computerized data, raises the idea of the types of formations that we will used to describe data gathered by Fermi as a descriptor of cosmos events in their unfolding.

Q&A with the Universe

From the quest for the most fundamental particles of matter to the mysteries of dark matter, supersymmetry, and extra dimensions, many of nature’s greatest puzzles are being probed at the Large Hadron Collider.

What is the form of the universe?

Physicists created the Standard Model to explain the form of the universe—the fundamental particles, their properties, and the forces that govern them. The predictions of this tried-and-true model have repeatedly proven accurate over the
years. However, there are still questions left unanswered. For this reason, physicists have theorized many possible extensions to the Standard Model. Several of these predict that at higher collision energies, like those at the LHC, we will
encounter new particles like the Z', pronounced " Z prime." It is a theoretical heavy boson whose discovery could be useful in developing new physics models. Depending on when and how we find a Z' boson, we will be able to draw more conclusions about the models it supports, whether they involve superstrings, extra dimensions, or a grand unified theory that explains everything in the universe. Whatever physicists discover beyond the Standard Model will open new frontiers for exploring the nature of the universe.

What is the universe made of?

Since the 1930s, scientists have been aware that the universe contains more than just regular matter. In fact, only a little over 4 percent of the universe is made of the matter that we can see.Of the remaining 96 percent, about 23 percent is dark matter and everything else is dark energy, a mysterious substance that creates a gravitational repulsion responsible for the universe’s accelerating expansion. One theory regarding dark matter is that it is made up of the as-yet-unseen partners of the particles that make up regular matter. In a supersymmetric universe, every ordinary particle has one of these superpartners. Experiments at the LHC may find evidence to support or reject their existence.

Are there extra dimensions?

We experience three dime nsions of space. However, the theory of relativity states that spacecan expand, contract, and bend. It’s possible, therefore, that we encounter only three spatial dimensions because they’re the only ones our size enables us to see, while other dimensions are so tiny that they are effectively hidden. Extra dimensions are integral to several theoretical models of the universe; string theory, for example, suggests as many as seven extra dimensions of space. The LHC is sensitive enough to detect extra dimensions ten billion times smaller than an atom. Experiments like ATLAS and CMS are hoping to gather information about how many other dimensions exist, what particles are associated with them, and how they are hidden.

What are the most basic building blocks of matter?

Particle physicists hope to explain the makeup of the universe by understanding it from its smallest, most basic parts. Today, the fundamental building blocks of the universe are believed to be quarks and leptons; however, some theorists believe that these particles are not fundamental after all. The theory of compositeness, for example, suggests that quarks are composed of even smaller particles. Efforts to look closely at quarks and leptons have been difficult. Quarks are especially challenging, as they are never found in isolation but instead join with other particles to form hadrons, such as the protons that collide in the LHC. With the LHC’s high energy levels, scientists hope to collect enough data about quarks to reveal whether anything smaller is hidden inside.

Why do some particles have mass?

Through the theory of relativity, we know that particles moving at the speed of light have no mass, while particles moving slower than light speed do have mass. Physicists theorize that the omnipresent Higgs field slows some particles to below light speed, and thus imbues them with mass. We can’t study the Higgs field directly, but it is possible that an accelerator could excite this field enough to "shake loose" Higgs boson particles, which physicists should be able to detect. After decades of searching, physicists believe that they are close to producing collisions at the energy level needed to detect Higgs bosons.

Saturday, May 01, 2010

This is not to support the religious right, or left, nor to induce fear(contentions of Peale in the article,) but to support the idea of thoughts actually changing the ownership of the property we have paid for when we come to our conclusions. What is the cost(belief) and one comes quickly to realizing the outcome has been provided for.